Spatial Ecology of Bacteria at the Microscale in Soil

Raynaud, Xavier; Nunan, Naoise

doi:10.1371/journal.pone.0087217

Cited by 359 publications

(334 citation statements)

References 52 publications

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“…Such variability, at spatial scales from centimetres to kilometres, is well known in other ecosystems. Microbial communities in terrestrial ecosystems demonstrate substantial variability over all spatial scales, from centimetres to kilometres [47], leading to similar variations in microbial metabolisms and metabolic outcomes that are detectable over similar spatial scales [52].…”

Section: Discussionmentioning

confidence: 99%

Microbial metabolism directly affects trace gases in (sub) polar snowpacks

Redeker

Chong

Aguion

et al. 2017

J. R. Soc. Interface.

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Concentrations of trace gases trapped in ice are considered to develop uniquely from direct snow/atmosphere interactions at the time of contact. This assumption relies upon limited or no biological, chemical or physical transformations occurring during transition from snow to firn to ice; a process that can take decades to complete. Here, we present the first evidence of environmental alteration due to in situ microbial metabolism of trace gases (methyl halides and dimethyl sulfide) in polar snow. We collected evidence for ongoing microbial metabolism from an Arctic and an Antarctic location during different years. Methyl iodide production in the snowpack decreased significantly after exposure to enhanced UV radiation. Our results also show large variations in the production and consumption of other methyl halides, including methyl bromide and methyl chloride, used in climate interpretations. These results suggest that this long-neglected microbial activity could constitute a potential source of error in climate history interpretations, by introducing a so far unappreciated source of bias in the quantification of atmospheric-derived trace gases trapped within the polar ice caps.

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Section: Discussionmentioning

confidence: 99%

Microbial metabolism directly affects trace gases in (sub) polar snowpacks

Redeker

Chong

Aguion

et al. 2017

J. R. Soc. Interface.

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“…Substrates, even at distances of micrometres or less, can be unavailable to microorganisms. Organic materials might not be attainable for decomposition due to adsorption on clay minerals and other surfaces or because they are trapped in pores or aggregates (Raynaud and Nunan 2014). In this study, we investigated whether the organic matter, which was incorporated into the soil through DSS addition, is an easily accessible substrate which increases microbial fertility and how DSS fulfils the principles of sustainable development.…”

Section: Introductionmentioning

confidence: 99%

Soil microbial functionality in response to dairy sewage sludge and mineral fertilisers application under winter rape

Oszust

Frąc

Lipiec

2015

Int. J. Environ. Sci. Technol.

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Microbial activity and the diversity of their catabolic potential would be stratified according to soil profile as a result of differing content of soil organic C and they would be altered by applying dairy sewage sludge (DSS) to the surface and subsequently ploughing. We applied 26 Mg ha -1 of DSS and the same nutrient dose of mineral fertilisers as an NPK reference to the soil before sowing winter rape (Brassica napus) in the field experiment. We evaluated the impact of the fertilisers on microbial activity, measured with dehydrogenase and respiratory activity, and diversity of the microbes' catabolic potential from non-rhizosphere and rhizosphere soil at selected depths. In the surface rhizosphere soil, there were significant increases in microbial catabolic potential ([25 %) and respiratory activity ([20 %) due to DSS application. All of the microbial parameter values in nonrhizosphere soil were higher at 0-20 than at 25-30 cm. These results are important for improving the management approach of diary sewage sludge application to agricultural soils in the context of increasing microbial activity in the soil profile and reducing mineral fertiliser use.

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“…X-Ray CT (images in this study were obtained using model HMX 225 manufactured by XTek systems Ltd., UK) has proven a powerful tool to characterise pore geometry ( Figure 1) at scales relevant to soil microbes with particular emphasis on bacteria [10,11] and has been used to characterize the effect of land management practices on soil architecture and subsequent microbial invasion [12,13]. …”

Section: Imaging Of Physical Soil Environmentmentioning

confidence: 99%

Visual Simulation of Soil-Microbial System Using GPGPU Technology

Falconer

Houston

2015

Computation

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General Purpose (use of) Graphics Processing Units (GPGPU) is a promising technology for simulation upscaling; in particular for bottom-up modelling approaches seeking to translate micro-scale system processes to macro-scale properties. Many existing simulations of soil ecosystems do not recover the emergent system scale properties and this may be a consequence of "missing" information at finer scales. Interpretation of model output can be challenging and we advocate the "built-in" visual simulation afforded by GPGPU implementations. We apply this GPGPU approach to a reaction-diffusion soil ecosystem model with the intent of linking micro (micron) and core (cm) spatial scales to investigate how microbes respond to changing environments and the consequences on soil respiration. The performance is evaluated in terms of computational speed up, spatial upscaling and visual feedback. We conclude that a GPGPU approach can significantly improve computational efficiency and offers the potential added benefit of visual immediacy. For massive spatial domains distribution over GPU devices may still be required.

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Spatial Ecology of Bacteria at the Microscale in Soil

Cited by 359 publications

References 52 publications

Microbial metabolism directly affects trace gases in (sub) polar snowpacks

Microbial metabolism directly affects trace gases in (sub) polar snowpacks

Soil microbial functionality in response to dairy sewage sludge and mineral fertilisers application under winter rape

Visual Simulation of Soil-Microbial System Using GPGPU Technology

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